Abstract

Synthetic dyes are vastly used for colouring numerous materials, although the adverse effects on environment are well recognized. In addition to developing the existing dyeing technologies more efficient and cleaner, the valorisation of natural dyes can enhance the sustainable development of dyeing industry. Natural indigo, derived from Isatis tinctoria, is a bio-based alternative for indigo produced via chemical synthesis routes. Owing to the insoluble character of indigo pigment, the dye requires conversion into soluble leucoindigo form prior to dyeing, which is often accomplished by using harsh sodium dithionite vat technique. During the processing from plant to dye attached on a fabric, indigo is transferred from the soluble leucoindigo form to the oxidized insoluble indigo and once more back to leucoindigo. Additionally, the oxidation is difficult to control and with traditional vat technique maintaining the leucoindigo through the dyeing often requires adding more reducing agent chemicals. Maintaining the soluble form throughout the process would enable lower number of processing steps and reduce the use of harmful chemical agents. In the present study, the stabilization of leucoindigo on nanocellulose matrix carrier was investigated with spectroscopic and photophysical methods. According to the results, leucoindigo was successfully stabilized on nanocellulose suspension, most likely due to the limited rate of oxygen diffusion into the viscous medium. Visual observations revealed that the leuco-form was retained even longer with natural indigo than synthetic indigo. This enhanced stability was attributed to the presence of radical scavenging species in natural indigo since the synthetic indigo did not show notable antioxidant properties. Given the promising results the paste formulation was demonstrated to be applicable for creating patterns on cotton using a screen-printing technique. Since the leucoindigo was stabilized on nanocellulose carrier, the need for re-reduction prior to dyeing was avoided and the amount of harmful reducing chemicals was reduced. These findings also show that the characteristics of natural dyes that are often considered disadvantageous compared to synthetic dyestuff, i.e. presence of co-products in the mixture, can however, create more value to the dyed material through new functionalities.

Highlights

  • The dyeing industry today relies heavily on synthetic-driven pro­ cesses owing to economical, availability and durability requirements (Bechtold et al, 2003)

  • We show that the composite of nanocellulose and natural indigo has anti­ oxidant properties, and that the purity of natural indigo from Isatis tinctoria in terms of indigo concentration is comparable to pure synthetic indigo

  • The small deviation of decay rate is likely due to the different environments of the molecules since the pure leucoindigo presented in Fig. 1b) is in dioxane solvent while in Fig. 1c) the leu­ coindigo is in nanocellulose suspension

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Summary

Introduction

The dyeing industry today relies heavily on synthetic-driven pro­ cesses owing to economical, availability and durability requirements (Bechtold et al, 2003). The dyeing process as such is a critical point of fashion industry causing significant negative environ­ mental impact, and approximately 20% of global industrial water pollution originates from textile dyeing and other wet processes (Kant, 2012). There have been only minor attempts to develop the existing dyeing processes towards more efficient and envi­ ronmentally friendly processes. Some advancements, such as supercrit­ ical carbon dioxide dyeing (De Giorgi et al, 2000) and digital printing (Tyler, 2005), have been made to reduce the water footprint and improve dyestuff utilization. Overcoming the environmental burden caused by textile wet processing requires revisiting and rethinking of existing processes

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